標題: A 16-Gb/s 14.7-mW Tri-Band Cognitive Serial Link Transmitter With Forwarded Clock to Enable PAM-16/256-QAM and Channel Response Detection
作者: Du, Yuan
Cho, Wei-Han
Huang, Po-Tsang
Li, Yilei
Wong, Chien-Heng
Du, Jieqiong
Kim, Yanghyo
Hu, Boyu
Du, Li
Liu, Chunchen
Lee, Sheau Jiung
Chang, Mau-Chung Frank
交大名義發表
National Chiao Tung University
關鍵字: Cognitive;continuous-time linear equalization (CTLE);decision feedback equalization (DFE);digital modulation;energy efficiency;feedforward equalization (FFE);forwarded clock;Inter-Symbol Interference (ISI);memory interface;uW/Gb/s/dB;multiband signaling;multidrop bus (MDB);multilevel signaling;nonreturn to zero (NRZ);pulse-amplitude modulation (PAM);quadrature amplitude modulation (QAM);serial link;source synchronous;transmitter (TX);wireline
公開日期: 1-四月-2017
摘要: A cognitive tri-band transmitter (TX) with a forwarded clock using multiband signaling and high-order digital signal modulations is presented for serial link applications. The TX features learning an arbitrary channel response by sending a sweep of continuous wave, detecting power level at the receiver side, and then adapting modulation scheme, data bandwidth, and carrier frequencies accordingly based on detected channel information. The supported modulation scheme ranges from nonreturn to zero/Quadrature phase shift keying (QPSK) to Pulse-amplitude modulation (PAM) 16/256-Quadrature amplitude modulation(QAM). The proposed highly reconfigurable TX is capable of dealing with low-cost serial channels, such as low-cost connectors, cables, or multidrop buses with deep and narrow notches in the frequency domain (e.g., a 40-dB loss at notches). The adaptive multiband scheme mitigates equalization requirements and enhances the energy efficiency by avoiding frequency notches and utilizing the maximum available signal-to-noise ratio and channel bandwidth. The implemented TX prototype consumes a 14.7-mW power and occupies 0.016 mm(2) in a 28-nm CMOS. It achieves a maximum data rate of 16 Gb/s with forwarded clock through one differential pair and the most energy efficient figure of merit of 20.4 mu W/Gb/s/dB, which is calculated based on power consumption of transmitting per gigabits per second data and simultaneously overcoming per decibel worst case channel loss within the Nyquist frequency.
URI: http://dx.doi.org/10.1109/JSSC.2016.2628049
http://hdl.handle.net/11536/145343
ISSN: 0018-9200
DOI: 10.1109/JSSC.2016.2628049
期刊: IEEE JOURNAL OF SOLID-STATE CIRCUITS
Volume: 52
起始頁: 1111
結束頁: 1122
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